Motor car



July 14,. 1936. w. B. STOUT 2,047,336

MOTOR CAR Filed April 16, 1934 l3 Sheets-Sheet l July 14, 1936, I w. B. STOUT- 2,047,336

MOTOR CAR Filed April 16, 1954 1:5 Sheets-Sheet 2 July 14, 1936. v v w. B. STOUT 2,047,336 3 MOTOR CAR I Filed April 16, 19 34 lSSheetS-Sheet 3 i fi Z05 05 v w Z 204 11178 J 194 I:

W. B. STOUT July 14, 1936.

MOTOR CAR l5 Sheets-Sheet 4 Filed April 16, 1954 m mllllllllllllllh July 14, 1936. w. B. s'rou'r 2,047,336

MOTOR CAR Filed April 16, 1934 v l3 Sheets-Sheet 5 W. B. STOUT July 14, 1936.

MOTOR CAR 15 Sheets-Sheet 6 Filed April 16, 1934 Jufly 14, 1936.. w. B. STOUT} 2,047,336

MOTOR CAR Filed April 16, 1954 15 Sheets-Sheet '7 JOZ July 14, 1936. w, B STOUT 2,@47,33

MOTOR CAR Filed April 16, 1954 15 Sheets-Sheet 8 July 14, 1936. w, 5, um 2,047,336

MOTOR CAR I Filed April 16, 1934 l3 Sheets-Sheet 9 July 14, 1936. w, B, STOUT 2,047,336

MOTOR .CAR

Filed April 16, 1934 13 Sheets-Sheet 10 #41, J Z12 Z 1 'July 14, 1936.- w. B. mm

MOTOR CAR Filed April 16, 1954 13 Sheets-Sheet 11 frwe W. B. STOUT July 14, 1936,

MOTOR CAR 13 Shets-Sheet 12 Filed April 16, 1934 y 6- 7 w. 3'. STOUT 2,047,336

" MOTOR CAR l3 Sheets-Sheet 13 Filed April 16, 1934 Patented July 14, 1936 part William Stout, Detroit, Mich, assignor to Stout llllotor qDar Corporation, lliearborn, Mich, a corporation of Michigan Application llpril 16, rear, semi No. more 32 iUlainos. (or. loo-r) This invention relates to motor cars and has for its principal objects to increase the wheel base and usable body space (length, width and head room) for a given over-all length, width and height of car, to reduce the aerodynamic resistance, to mount the power plant at the rear and support it independently of the body, to make the power plant easily accessible while in place and readily removable as a sub-assembly for repair and replacement, to resiliently support the differential gearing and housing, to exclude motor noise and smell from the body, to allow independent up and down movement of, each wheel, to support the body resiliently from points above its center of gravity and insulate it from vibrations and road noise, and to reduce the weight and the power required to drive the car.

An embodiment taking advantage of parts and .sulo-assemblies subject to quantity production is shown in the drawings in which Fig. l is a side elevation about one-twentyfifth size;

Fig.2 is an enlarged side elevation of the rear portion, about one-ninth size, with the portion of the body shell and other parts removed to expose the power plant;'

' Fig. 3 is a rear elevation with the shell of the body and the muiiier removed and parts of the frame broken away;

Fig. 4 is a transverse section taken on the line l- 3 of Fig. 2, looking rearwardly;

Fig. 5 is a plan view of the rear end of the car, the shell being removed and portions of the frame being broken away;

Fig. 6 is a side elevation of the lower portion of the motor showing the support for the diiferential, the rear axlebeing in section;

Fig. 'l' is a longitudinal vertical section taken on the line 'l-l of Fig. 5, showing a resilient bumper for transmitting severe blows at the rear to the frame that supports the motor;

Fig. 8 is a horizontal section on the line t--ll of Fig. 2, looking downwardly;

Fig. 9 is a section on the line ll-ll oi Fig. 3,- through one of the rear struts;

. Fig. 10 is a section on the line lt-elll of Fig. 3,

' showing the joint between one of the radius rods and a portion of the body frame;

Fig. ll is a section on the line ll--ll of Fig. 5, showing the connection between the front end of the power plant and a torque brace from the body frame;

Fig. 12 is a rear elevation of the motor car with one cover of the power plant removed and showing the position of the parts as a rear wheel passes over a bump;

Figs. 13, 14 and 15 are diagrams in side elevation, plan and rear elevation of the mounting for the power plant, illustrating the lines of force; 5

Fig. 16 is a longitudinal section through a portion of the rear axle adjacent to the differential;

Fig. 17 is a transverse section taken on line Ill-ll of Fig. 16;

Fig. 18 is a perspective view taken from the 310 right rear of the motor car;

Fig. 19 is a side elevation showing how the body may be removed from the rear axle and power plant assembly;

Figs. 20 and 21 are plan and side elevations of 15 the motor car with the shell of the body removed, and certain parts omitted to show the general arrangement without confusion;

Fig. 22 is a front elevation with the shell of the body and a part or" the frame broken away;

Fig. 23 is a section talren on the line 2tl-2t of Fig. 21, looking forwardly, with the shell of the 7 body being removed and a part of the frame being broken away;

Fig. 24 is a front elevation with a portion of 25 the body broken away showing the position or the parts when a front wheel passes over a hump;

Figs. 25 and 26 are horizontal sections taken respectively on the line and 2tilt of Fig. 23, loolring downwardly;

Fig. 2'? is a vertical section, illustrating the joint between the front axle sections and the body irame, with parts broken away.

Figs. 28 and 29 are partial vertical sections taken on the lines til-til and lt-tll respectively of Fig. 22;

Fig. 30 is a section taken on the line illllltl of Fig. 29, looking forwardly;

Fig. 31 is a section talren on the line fil -Ell of 4.0 Fig. 28;

Fig. 32 is a section talren on the line till-ill! of Fig. 31;

Fig. 33 is a diagram of the lines of force involved in the support for the front of the body;

Fig. 34 is a plan View of the frontend of the motor car with a portion of the shell removed! to show the the carrier and the front axle mechanism; I

Fig. 35 is a horizontal section taken on the line 2F-tii of Fig. 21, looking downwardly;

Fig. 36'is a transverse section taken on line Elli-3t of Fig. 35; and

Fig. 37 is a diagram in perspective showing the 659,712, filed March 6, 1933,

general arrangement for carrying the body and the power plant.

Fig. 38 is a partial longitudinal section through the rearend of the car on line 38-38 of Fig. 39 to bring out features of the engine .cooling system;

Fig. 39 is a plan view of the rear end of the car with parts broken away for the same pur- Fig. 40 is a. fragment of a front axle construction embodying a modification;

Figs. 41 and 42 are longitudinal and transverse sections through the rear end of the car, illustrating a modified organization including a radial engine.

But these illustrations and the description of the particular constructions are used for the purpose of disclosure only and not to indicate that the invention is so limited;

General description By looking first at Fig. 37 it will be seen that the body, represented roughly as a; box In, is resiliently' borne on struts ll-l l, at the front, and l2l2 at the rear, all of which extend to such height that the center of mass of the body is, in

effect, swung ,from the tops of four columns,

standing on the axles, one close to each wheel.

Turning to Figs. 13, 14 and 15, it will be found that the motor i3, transmission gearing l4 and differential gearing l5 are, in effect, swung between and from the top of the two rear columns l2l2, and borne thereby independently of the support for the body at the rear end. This general scheme of carrying the load makes for stability and smoothness in travel, and goes well with bodies shaped to reduce aerodynamic resistance (Figs. 1, 12 and 24) and wheels arranged ior independent up and down movement in passing over individual obstructions (Figs. 12 and 24). a

The body here illustrated is similar to that disclosed in my prior application, Serial No.

in that a longitudinal section, or any section at an angle to the front up to about 45, is shaped approximately like an air-foil or a cross section of an aeroplane wing. There is a slight deviation from the air-foil at the front, as indicated by IS, in Fig. l, where an extension is made to accommodate a. spare tire carrier, but that has an almost inappreciable effect onthe air resistance. There are no running boards, the floor .line I! is approximately on a level with the axes of the wheels I8 (Figs. 1 and 21). The side walls rise in outward curves from the floor line and turn inwardly to present easy sloping sides (Figs. 12,

24 and 36) blending with the gently curved top. The frame work is a skeleton of tubing (prefer-- ably seamless chrome molybdenum steel, but choicewill vary) welded at the joints into one hollow truss, spanning the distance between the supporting struts ll, l2. It is covered externally I and internally with shells 2i (made of sheet ma-- terialsteel, aluminum, laminated wood and,

aluminum sheets, and such like, welded, riveted or screwed-to theframe work) and the intervening spaces are packed with sound and heat insulating material.

Windows 22, 23,45, 25, 25, 21', 28 and 29 fitted with laminated glass; afford generous vision in 8.11 directi0n3. V

Both the frame and the shell extend over and about the upper-portion of the wheels, the lower portion of which form practically the only projection beyond 'the enclosure "of the body. The wheels are of small diameter and include low pressure tires of great cross section, secured to The rear end The rear axle is, for the most part, like that used in a model AA Ford, and the rear wheel brakes, etc., correspond.

At each side of the differential housing 30 the axle housings 3| are cut away, and each is equipped with a flanged steel forging 32 (Fig. 16) telescoping therewith and welded at 33. Each axle shaft 34 is shortened, and its inner end journaled in roller bearings 35 fitted to the forging 32, and held in place by the cap 36. Interposed between the axle shafts 34 and stub shafts 31, journaledon bearings 38, in the differential housing 30, is a universal joint, including two cross arms 39 fixed to the respective shaft ends, and connected with a sheet metal ring structure 40 by pins 4| fitted with steel and rubber bushings 42 of familiar construction.

Each strut l2 for supporting the rear end of the body and the power plant includes, in this instance, a conventional spring 43 (Fig. 9) between flanged caps 44 and surrounding the telescoping cylinder 45 and 46, forming an assembly known as an oleo.

Many forms of these devices are well known and it will be suiiicient to say that they comprise some sort of spring or other resilient unit associated with a hydraulic brake which controls the yield and rebound of the spring.

. Each lower cap 44 is welded to a. conical fitting 41, threaded to receive a bolt 48 having a flat head 49, hinged by, a pin 50 to a lug 5|, welded on top of the corresponding rear axlehouslng 3|, adjacent to the wheeL' Each upper cap 44 is pivoted to a fork 52 on the bottom of a plate 53 (Fig. 9). The pivot bolts 54 and 55 are fitted with rubber insulators 56 comprising a rubber sleeve under endwise compression, and one or more steel bushings.

Each plate.53 has a laterally directed wing 51 (Fig. 3) connected to a tubular cross strut 58.

Each plate 53 also has two downwardly inclined wings 59 and 60 (Fig. 9) connected to the upper ends of inclined stays, or tubular straps. GI and 62, the lower ends of which are bolted to the respective lugs 63 and 84, projecting from crank case of the motor l3 (see Figs. 4, 5, 13, 14 and 15).

' ing is replaced by a special head 65 (Figs. 2 and 13) which, together with a chain housing 65, '1

supports the front end of the change speed gearing housing l4, the rear end of which is connected by a flanged tube 6] with the front side of the differential housing 30. The motor, the chain housing, transmission casing and the differential housing thus become fixed with respect to each 9,047,386 other and form a unit resiliently mounted from the struts l2. Split collars 68 at each side of the diiferential housing (Figs. 3, 6 and 16) are connected by tubular straps or stays 69 and ill, with the lugs 63 and M on the engine casing. Cross braces Ii (Fig. 3) connect the stays t9 and it into a rigid frame.

A flanged sleeve l2 (Figs. 2, 5 and 11) is bolted to the top of the chain housing 66 and receives a rubber insulating bushing l3, surrounding a bolt it, extending through the flattened ends iii of V- shaped brackets it projecting downwardly and inwardly from the body frame.

The power plant is substantially balanced on the struts it and the connection last described between the front of that unit and the frame is chiefly to resist driving torque.

The driving thrust and braking stresses from the rear wheels are transmitted to the body frame by radius rods ll (Figs. 2, 8, 1i and 19) inclining from rear axle housings 3i at the base of the struts it to the body frame at about the floor line and in front of the universals in the rear axles. The radius rods consist of two tubes welded to a fork it (Fig. 9) pivoted by a pin it to a lug til, welded on the front side of each axle housing ti. The joint between the fork it and the pin ill is fitted with rubber insulating bushings ti. The front end of each radius rod (Fig. ill) is formed into a fork t2, receiving rubber washers til on each side of a plate at projecting rearwardly from the body frame. The fork and the plate are pivoted together by a bolt ilb surrounded by a sleeve tt.

Turning to Figs. 15 and. 19, it will be seen that the power plant, rear axle and rear wheels form a separate assembly ordinarily received in and enclosed by the rear portion of the body shell.

Hy removing the bolts iltlt and be (Figs. 5 and ill), the rear axle and power plant assembly is completely disconnected from the body and the latter may be raised (as indicated in Fig. lb) and rolled away on the front wheels.

The plates M, by which the radius rods are connected to the body frame, are welded to a transverse tube ill (Figs. 2 and b) at about the rear end of the floor. Above this there are other transverse tubes llti, tt, bill and ii i, which together with plates at and insulating material form transverse partition, or sound prooi bulkhead dividing the motor space from the passenger space, or body proper.

The muffler Ml (Figs. 2 and 19) is carried by the stays ill on the opposite side of the power plant trend the passenger space and near the lower rear edge of the body shell. All the joints be tween the power plant assembly and the body frame being insulated with rubber, there is practi cally no vibration or noise transmitted to the interior.

The body frame includes two pedestals it (Flash, 3, l8 and 19) having plates at corresponding toplates bit of the struts it, and sup ported on the latter through thick rubber pads The plates and the rubber pads are secured together by bolts The rear part oi the body shell (Fig. l2) is formed by two doors lit, hinged at tilt, to normally told together and close the power plant chamber, but when swung open adording goinplete access to all parts of the power plant.

at the extreme rear of the body the frame in cludes a curved tube ilii (Figs. 2, 5 and 19) which,

I05, to cooperate with the flat faces I 06 on the ends of a stay ill'l (Fig. 7) connected to the lugs 64 at the rear end of the motor. Thus a severe shock at the rear of the car wouldbe yieldingly transmitted to the heavy mass of the power plant.

Engine cooling system The cooling radiators We .are supported on each side of the bodyframe just to the rear of a the bulkhead and cooperate with fans tilt driven by pulleys lid on the front end of the crank shaft (Figs. 2, 38 and 39).

Air enters at each side through a set of louvres ill and is directed downwardly by ducts Mil to the fans tilt. The rear wall lid of each duct is ofiset forwardly, as indicated at itii, and cooperates with the plate iii to form a sort of fan housing, enlarging towards the corresponding radiator tilt. The lower portion of the engine space is closed by a dust pan ill extending rearwardly from the floor line substantially in continuation of it, and iornied up to make mud guards ill and provide clearance for the radius rods ll, therear axle sections ti, the transmission casing it and the difierential casing id. The extreme rear edge il l (Figs. 2, l2 and 38) of the pan is below and substantially parallel to the rolled rear edge tilt of the body shell, thereby providing a long, relatively narrow discharge out let for the cooling air.

From this it will be seen that the whole motor chamber, or space, is kept under a slight pressure and the cooling air, after passing through the radiators ltd, sweeps overthe motor and accessories, on its way to the discharge atthe lower rear of the car.

The louvres preierably open upwardly (shown best in Figs, 2 and 3%) hence, in case of rain some water will enter, and the pan i232 is provided with openings ilil (Fig. Sill) each side, adiacent to the bulhhead, to let the water escape.

The front end The front sale is in two sections hinged in the middle to allow the wheels up and down move ment within the prescribed lirnits.

Each section of the trout anle (Figs. 22 to 26 inclusive) includes tubes and Hill with their flattened outer ends and welded to a short stub of a conventional trout axle (1011- nected by a steering hnucirle lilli (Fig. 22) with a spindle journaled in a trout wheel ill, equipped with brakes. etc, as usual.

The inner ends oi? the tubes itli and till are spread apart, as best shown in Figs. 26 and 35, and termuiate in bearings receiving insulating rubber bushings it? and bolts by which they are hinged to plates itil (Figs. 22, 26 and 27) welded to a tube t lt, extending lengthwise along the bottom of the body ifrani'e;

The flattened end portions and are turned upwardly to form hinge flanges i li (Figs. 22 and 2t) pivoted by a bolt to the lower end ot a fitting Md, welded to the lower cap (Figs. 23 and 2d) of an oleo the upper cap Mt of which is welded to a stern The front end oi the body training includes two pedestals in. the form oi plates it'll (Figs. 22, 23 and 28) to which the stems are pivoted by bolts on, and insulating rubber bushings ltd.

The upper end of each iiltting Mil (Figs. 22, 23, 25 and 2b) is pivoted to links ltd and 11st, which have their lorward enm spread apart and pivoted to transverse ears tilt of the body frame, and

serve to stay the struts during the up and down movement of the wheels.

Fig. 24 illustrates the posit ons of the parts assumed as the front wheels run over a bump.

-In some instances the movements of the front wheel, as indicated in this figure, will be objectionable, in which case the short axle stub I68 (Fig. 40) may be fixed to plates I10, in turn fixed to the base fitting I1I of the front oleo, thereby making the wheel conform very nearly to the up and down movements of the lower portion of the oleo strut. The pivotal movement is allowed by joining the tubes I12 and I13 (corresponding to the tubes I30 and I3I in Figs.'24 to 26) with a tubular fitting I14, journaled on a pintle 258 equipped with an insulating rubber bushing 258.

, The steerina gear The steering knuckle arms I58 (Figs. 25 and 26) are connected by universals I54 to the remote ends of links I55, the adjacent ends of which are connected by other universals I56 with a union I51 pivoted to the rear end of an intermediate lever I58, fulcrumed at I59 on the underside of the tube I40 and having its front end connected by universal I60 to one end of a connecting rod I6I, the opposite end of which is connected by universal I62 with the steering arm I88 which is operated by a conventional steering post I64 and gear assembly I85 mounted on brackets I 88, I81 and I88, welded to the body frame work (Figs. 29 and 30).

The bod?! The lower portion of the body frame work is best shown in the plan section (Fig.35) which is taken on the line 35-.35 of Fig. 21. There are five transverse tubes I15, I18, I11,- I18 and 81, the latter of which is shorter than the others and is supplemented by tubes I80 to the rear at each side, having their inner ends braced by the tubes Ill. The transverse tubes are connected by four longitudinal tubes I88, I84,I85 and I88 (as best appears in Figs. 21 and '35, the tube I0 I, heretofore mentioned in connection with the bumpers I05, Figs. 2, 5 and 19, extends around each end and lengthwise at each side of the body just above the floor, except where cut away for the doors I88, and there it is supplemented by short tubes I88 at a lower level).

Towards the front there are diagonal braces I80 converging at the junction of the tube I40 with an intermediate portion of the cross tube I15. This last mentioned cross tube I15 is reenforced by a short angle I8I (Figs. 25, 28 and 35) and in line with the longitudinal tubes I84, I85, there are truss tubes I82 (Figs. 28 and 36) extending from the angle I8I rearwardly to the transverse tube 81 opposite to the connection with the radius rods 11. There are also crosswise truss tubes I18 between the truss tubes I82 and connecting them with the longitudinal tubes I88 and I85 respectively (Fig. 36).

Turning now. to Figs. 20 and 21, it will be seen that the transverse tubes I15, I11, I18 and the short tubes I80, extend upwardly at each side and over the top of the body frame, while the transverse tube I15 extends up each side to a junction I88 at the lower rear corner of the window 28.

Above the tube IN on the right, a tube I84 extends lengthwise from the tube I11 at the front side of the door to the junction I83, to and between the pedestals I41 around to the left (Fig. 20) to the other junction I83 adjacent to the left door. It is omitted at the door but extends rearwardly from the rear side thereof to the tube I18 where it curves downwardly and then outwardly to the tube IOI at the junction I95.

At the right side to the rear of the door I88 there is a like continuation of the tube I84 to a similar junction I85with the tube IOI. Above the tube I84 there is a tube I86 (Figs. 20 and 21) extending along between the windows 22 and 28 over the window 24 (which is in the left door) 25, 26 (which is in the right door) 21, to the junctions I81 opposite to the outer corners of the windows 28, and from those junctions to a manifold junction I88, which is connected by a single tube I88 with the tube IOI at the extreme rear of the car.

A tube 200 runs rearwardly from each corner of the front overhead window 29 (Fig.20) to the tube I11 and then is deflected outwardly and downwardly to a junction between the tubes I86 and I18. A ridge tube 20I extends along the top of the car from the window 28 to the tube I above and between the rear windows 28.

These windows (Fig. 12) are substantially upright in little valleys on opposite sides of a ridge 202 formed of sheet metal to continue the contour of the shell and make provision for tubing connecting the inlet side of the carburetor with the interior of the passenger space overhead.

Those valleys are just above and in front of the two doors 88 (Fig. 12) covering the power Plant.

Turning again to Figs. 20 and 21, at the rear, it will be seen that there are tubes 203 running from the manifold junction I98 to each pedestal and thence forwardly and downwardly to junctions with the tubes I80, IN and I18, Also other tubes 204 extend downwardly from the tube I84 to the tubes 20: at the functions with the tubes IOI.

Taking Figs. 20, 21, 22, 23, and 34, it will be seen that the tubes 200, extending along the top, may be considered as extending downwardly and outwardly at each side of the front window. 22 across the pedestals I 41 down to manifold junctions 205 at each side of the car in front,'from which braces I82 run to the front end of the tube I40 (to which the front axle sections are hinged). Junctions 205 are stayed laterally by a transverse tube 208 forming part of a stout truss work, best indicated generally at 201, (Fig. 23) inclined to the front transverse floor tube I15.

- The front end of the tube I40 is also braced by a tube 208 (Figs. 21 and 22) inclining upwardly and outwardly to the extreme front portion of the front transverse floor tube I15 with th e/ped- 65 es'tals I41 and serve to support the footjioards,

not shown.

The rear portion 2I8 (Fig. 28), of the bottom arch 2I4 is connected by inclined stays 2" with the upturned part of the tube I15 and forms the support for the instrument board, not shown.

The front portion of the shell (Figs. 24 and 34) is provided with the door-,2I8 hinged at 2I8 aifording access to the spare tire carrier.

The junctions 205 at each side are also braced to each junction I93 by tube 220, and to the horizontal tube llll by tubes22l and 222. Another transverse tube 223 parallel to the tube 206 (between the junctions 205) extends from the junction of one tube 22l with the tube llll, to the other and forms a sort of cord brace for the bowed front end of the latter.

At the rear of the passenger space, the bottom transverse tube 81 is connected to the upper transverse tubes 89 and 90 by inclined braces 224 and 225 (Figs. 2, 5 and 20).

Radial engine drive (Figsf41 and 42) The invention lends itself very readily to em-v bodiments for utilizing the highly developed radial engines as a source of power. One arrangement is shown more or less diagrammaticallyin Figs. 41 and 42, where 226 indicates a radial engine mounted in an air drum or barrel 2211, the upper edge of which is attached to an annular ring of rubber 228 which, in turn, ismade fast to a tubular ring 229 that serves in place of the pedestals 9% in the first form described. The lower portion of the drum 22'i is closed except at the rear, where it forms, with the curved plate 230, a discharge for cooling air drawn in through the louvres 23! by the fan 232. [7

The drive from the engine is through a clutch 231i and an automatic transmission 2% to the differential 235, all diagrammatically shown in the drawings, because the detail here is a matter of selection.

At each side of the drum (Fig. 42) there are brackets 236 which are pivoted at 221i to the upper ends of oleos 238 resting on the rear axles 229, as described in connection with the other form. At the lower side the drum carries straps 2% for supporting the differential 225.

This arrangement is of especial advantage at the present time where more power is required than can be developed by the small production engines of the type illustrated in the other form described.

The use of the oleos for the supporting struts i II and i2 is an incident born of the fact that they are readily available and furnish the damped or retarded resiliency desired. The particular form shown in Fig. 9 allows the spring to yield readily under shock and retards the recoil. A great many substitutes may be readily selected or devised.

In the car shown the rear oleos are inclined forwardly and inwardly as a concession to the particular conditions. Under other circumstances they would be inclined rearwardly and inwardly like the front oleos to meet the road shocks more directly..

The scheme of mounting the motor, etc., sepa rate from the body frame can be carried outin connection with the front axlesif for any reason it is preferred to have the motor in front.

Various other changes will occuras the invention is put to use by others and an attempt to suggest or illustrate them would be burdensome.

Certain of the inventivefeatures of the rear window construction and the. engine mounting disclosed in this application are described more ing housing for driving each wheel, a resilient strut rising from each axle housing adjacent to its wheel, a body having its rear end carried by the struts, a motor carried by the struts, means connecting the motor with the axles for driving them and a radius rod connecting each axle housing adjacent to each wheel with the body in front of' the axle housing.

2. In a motor car, a pair of wheels, an axle housing for each wheel, a driving axle for each wheel in its housing, a motor, a transmission mechanism connecting the motor with the driving axles, means for resiliently supporting the motor, including struts, one rising from each axle housing adjacent to the wheel, a body carried by the struts and radius rods connecting the axle housings with the body.

3. In a motor car, a pair of wheels, an axle housing for each wheel, a driving axle for each wheel in its housing, a motor, a differential gearing driven by the motor, a universal joint between the differential gearing and each driving axle, means for resiliently supporting the motor, including struts, one rising from each axle housing adjacent to the wheel, a body carried by the struts and a radius rod connecting each axle housing adjacent to the wheel with the body.

4. In a motor car, a body having a separate chamber adjacent to an end and open at the bottom, an axle, a power plant in the chamber,

struts rising from the end portions of the axle into the chamber, and means for supporting the power plant and the body on the struts. v

' 5. In a motor car, a body having a separate chamber adjacent to an end and open at the bottom, an axle, a power plant in the chamber, struts rising from the end portions of the axle into the chamber, means for supporting the power plant and the body on the struts, and radius rods connecting the axle and the body.

6. In a motor car, a car body having a body frame, a pair of wheels,-axle sections, means for pivotally connecting certain of said sections directly to the body frame to swing about a substantially horizontal axis, a steering knuckle for each axle section and resilient means for supporting the front end of the body including a strut rising from an axle section adjacent to the steering knuckle to a point above the center of gravity of the body. 4

7. In a motor car, a car body having a body frame, axle sections, means for pivotally connecting certain of said axle sections directly to the body frame adjacent to the bottom to swing about a substantially horizontal axis, a steering knuckle and wheel for each axle section, a strut rising from each axle section to apoint above the center of gravity of the car body, and resilient means for supporting the car body on the struts.

8. In a motor car, a car body, forked axle sections-with the ends of the forks pivoted to the body to swing up and down about an axis extending lengthwise to the car, a steering knuckle carried by each axle section, and a resilient support for the body including a strut fast to each axle section and extending up into the body above the center of gravity thereof and secured directly thereto.

9. In a motor carfi'ront and rear sectional 70 axles, wheels therefor, a body, and an inclined resilient strut movably connected to and extending upwardly from the end portion of each -axle and connected to the body above the horiaontal plane of the center of gravity thereof, said body enclosing said struts.

10. In a motor car, a body, a pair of wheels, axle sections, each pivoted to the body to swing in a vertical plane about a substantially horizontal axis, a steering knuckle for each axle section, resilient means for supporting the front end of the body including a strut rising from an axle section adjacent to the steering knuckle at each side of the car to a point abovethe center of gravity of the body, and steering mechanism including a steering knuckle arm for each steering knuckle, an intermediate lever mounted on the body, links connecting the intermediate lever and the steering knuckle arms and means for moving the intermediate lever.

11. In a motor car, a pair of wheels, an axle,

a difierential supported by the axle, a strut rising from the axle adjacent to each wheel, a radial engine suspended from the struts and connected with the differential.

\ 12. In a motor car, a body, a pair of wheels, an axle for the wheels, a strut rising from the axle adjacent to each wheel for supporting said body, and a motor between and suspended from the struts independent of the body.

13. In a motor car, a body, a pair of wheels, an axle for the wheels, means including a strut rising from the axle adjacent to each wheel for supporting said body, 'a motor between and suspended irom the struts independent of the body, and diflerential gearing suspended from the motor.

14. In a motor car, a body, a pair of wheels, an axle for the wheels, means for resiliently mounting the body including a strut rising from the axle adjacent to each wheel, and a motor borne by the struts independently of the body.

15. In a motor car, a body, a pair of wheels, an axle for the wheels, means for resiliently mounting the body including a strut rising from the axle adjacent to each wheel, a motor borne by the struts independently of the body, and means to connect the motor to the body to resist torque.

16. In a motor car, a body, a pair of wheels, an axle section for each wheel pivoted with respect to the body, a motor, and means for mounting the motor independent of support from the body including a strut rising from each axle section adjacent to the corresponding wheel to points above the center of gravity of the motor.

1'7. In a motor car, abody, a pair oi. wheels, an axle section for each wheel pivoted with respect to the body, a motor, and means for mounting the motor independent of support from the body including a strut rising from each axle section adjacent to the corresponding wheel to points above the center oi gravity of the motor,'and a cross strut connecting the upper portions of the first two struts.

18. In a motor vehicle, an axle comprising intermediate and end sections pivotally connected together, a diflerential carried by the intermediate section, a motor rigidly connected to said intermediate section, and means for yieldably supporting said motor from said end sections.

19. In a motor vehicle, a body, front and rear axles, each axle comprising intermediate and end sections pivotally connected together, means for rigidly connecting said body to certain of said sections, means for resiliently supporting said body from certain other of said sections, the intermediate section of one of said axles comprising a differential, a motor fixed relative to said difierential, and means for resiliently sup porting said motor from said end sections.

20. In a motor vehicle, a body, front and rear axles, each axle comprising an intermediate sec- 5 tion, end sections and means for pivotally connecting said end sections to said intermediate section for permitting the end sections to swing in a vertical plane, means for rigidly mounting said body on said intermediate sections, and resilient means for supporting said body from said end sections.

21. In a motor vehicle, a body, front and rear axles, said rear axle comprising a plurality of sections pivotally connected together, a pair of standards for each axle, each standard pivotally connected at one end to the corresponding axle outwardly of the intermediate section thereof and at its other end attached to said body, means for holding the connections between the 20 standards for each axle, respectively, at a fixed distance apart, and means for resiliently resisting the relative movement of said standards and axles.

22. In a motor vehicle having a body, means 25 including wheels and front and rear axles for supporting said body, said rear axle comprising a plurality of articulated sections, a removable power unit comprising said rear axle and wheels thereon, a motor, a differential between the sec- 30 tions of said axle and means for supporting said motor and difierential from said rear axle, and means for detachably connecting said unit to said vehicle whereby said unit may be readily removed from said vehicle to afford access to said 35 motor.

23. In a motorvehicle, a vehicle body, means including a power unit for supporting said body and forpropelling said vehicle, said unitcomprising a sectional axle, wheels on said axle, a motor, resilient supporting means pivotally connected to and extending upward from said axle for resiliently supporting said motor, means for rigidly connecting said motor to said supporting means, and means for detachably connecting said body to said supporting means.

24. In a motor vehicle, axle sections, a motor,

means for resiliently mounting said motor on certain of said sections comprising resilient sup porting members on said sections, means for rigidly connecting certain portions of said sections to said motor to prevent relative movement thereof, and flexible connections between certain other portions of said sections and motor for providing relative movement between said motor and members.

25. In a motor vehicle, front and rear sectional axles, means for pivotally connecting said sections together to provide relative vertical movement of said sections, resilient supporting 00 members pivotally connected to said axles and extending upwardly andinwardly therefrom, a body, and means for flexibly connecting said body to the upper portion of said members above the center oi! gravity 01. said body whereby on 65 turning curves at high speeds said members will cause banking of said body.

26. In a motor vehicle, a body, an articulated axle, a radial engine above said axle for driving the same, and resilient supporting members pivotally connected to said axle and motor for supporting an annular rubber positioning member between said body and motor.

27. In a motor car, front and rear sectional axles, means for pivotally connecting said secll tions together to provide for relative vertical movement of the said sections, wheels therefor, a vehicle body, and means to support the body. on the axles including four resilient struts, each rising from a different axle section and connected to said body and means at each end of said body for rigidly connecting the same to the intermediate sections of said axles.

28.11. a motor car, front and rear sectional axles, wheels therefor, a motor on .the rear axle for propellingsaid car, a.v body, and four inclined struts, one rising from anaxle section adjacent to each wheel and connecting to the body at points above the center of gravity of said body.

29. Ina motor car, front and rear axles, wheels. therefor, said rear axle having intermediate and end sections, a motor on the intermediate section of the rear axle for propelling saidcar, a

.body, a strut on each axle adjacent to each wheel extending up into the body, means on the upper portions oi! the struts for mounting the body on the struts, and means, tor-connecting the forward portion of said motor to said body.

v 30. In a motor car, a car body provided with a rear compartment having a discharge opening at its rear, 9. rear axle, a motor carried thereby within said compartment, and means to cool the motor including a fan taking air in from above and forcing it across saidmotor within said compartment and from thence out through a restricted opening inthe rear lower portion of. said compartment whereby air within said com- 5 partment will be maintained at slightly super-1 atmospheric pressure during the, operation of said motor.

31, In a motor vehicle provided with a body, an axle comprising a plurality of sections, means 10 for resiliently supporting said body from said axle, a motor, means for rigidly connecting said motor to certain of said sections, means for resiliently connecting said motor to certain other of said sections, and means for directly connectl5. ing said motor to said body.

32, In a motor vehicle, front and rear sectional axles, a vehicle body, resilient supporting means extending upwardly from said axles, a

'motor rigidly mounted'on certain of the axle sec- 20 tions, means for movably connecting said motor to said supporting means, and means connecting said supporting means to said body for resiliently supporting the same whereby on turning curves at high speeds the mounting of said body 'will 25 cause banking thereof.

WZILHAM B. STOUT. 

